Effective confinement as origin of the equivalence of kinetic temperature and fluctuation-dissipation ratio in a dense shear-driven suspension

Lander, Boris; Seifert, Udo; Speck, Thomas

doi:10.1103/physreve.85.021103

Cited by 13 publications

(15 citation statements)

References 42 publications

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“…In the static limit ( = 0), several aspects of this problem have been addressed previously, for example, diffusion [38], inertial effects [31], dynamic properties [33], fluctuationdissipation relations [34,39], the probability distribution in the overdamped limit [32], or retardation effects [40]. In the following, we focus on the oscillatory case with > 0 and explore the influence of the periodic flow on the dynamics of a single particle (Sec.…”

Section: Modelmentioning

confidence: 99%

“…Compared to static shear flow [31,34], the coefficient matrix A(t) now becomes time dependent and reads…”

Section: A Solution Of Langevin Equationmentioning

confidence: 99%

“…This could be pivotal to constructing new antenna systems, for example, ultrasonic emitters [30]. Second, more fundamentally, even the case of a single trapped particle is interesting since analytical solutions have been presented for the linear-shear case [31][32][33][34]. Due to the stochastic Brownian force, these solutions are nontrivial and exhibit interesting particle distribution functions and shearinduced cross-correlations.…”

Section: Introductionmentioning

confidence: 99%

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Resonant behavior of trapped Brownian particles in an oscillatory shear flow

Kählert

Löwen

2012

Phys. Rev. E

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The response of harmonically trapped Brownian particles to an externally imposed oscillatory shear flow is explored by theory and computer simulation. The special case of a single trapped particle is solved analytically. We present explicit results for the time-dependent density and the velocity distribution. The response of the many-body problem is studied by computer simulations. In particular, we investigate the influence of oscillatory shear flow on the internal modes of the cluster. As a function of the shear oscillation frequency, we find resonant behavior for certain (antisymmetric) normal modes, implying that they can be efficiently excited by oscillatory shear. Our results are verifiable in experiments on dusty plasmas and trapped colloidal dispersions.

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Section: Modelmentioning

confidence: 99%

“…Compared to static shear flow [31,34], the coefficient matrix A(t) now becomes time dependent and reads…”

Section: A Solution Of Langevin Equationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Resonant behavior of trapped Brownian particles in an oscillatory shear flow

Kählert

Löwen

2012

Phys. Rev. E

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“…However, in complex fluids or biological matter this kind of dynamical time-scale separation is the exception rather than the rule. In this regime of mixed time scales, time-dependent FDRs have been studied, i.a., for active matter [5,11,[14][15][16][17][18][19], sheared colloidal suspensions [10,20,21] and single biomolecules [12]. In a heuristic approach introduced in the glassy context [2,7] and revisited for driven Brownian [15,16,22] and ageing [23] systems, the effective temperature is identified with the measurement by a thermometer.…”

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confidence: 99%

Driven Brownian particle as a paradigm for a nonequilibrium heat bath: Effective temperature and cyclic work extraction

et al. 2017

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We apply the concept of a frequency-dependent effective temperature based on the fluctuationdissipation ratio to a driven Brownian particle in a nonequilibrium steady state. Using this system as a thermostat for a weakly coupled harmonic oscillator, the oscillator thermalizes according to a canonical distribution at the respective effective temperature across the entire frequency spectrum. By turning the oscillator from a passive "thermometer" into a heat engine, we realize the cyclic extraction of work from a single thermal reservoir, which is feasible only due to its nonequilibrium nature.Introduction. -Cornerstone principles of equilibrium statistical mechanics, such as the equipartition of energy or the fluctuation-dissipation theorem (FDT) [1], are generally not directly applicable to ageing (e.g., glasses [2]) or driven systems (e.g., active particles [3][4][5]). Sometimes equilibrium relations can be reconciled by introducing an "effective" quantity that compensates for nonequilibrium deviations. In this spirit, the FDT can be formally maintained by interpreting the fluctuation-dissipation ratio (FDR) as an effective temperature [6][7][8][9]. However, a nonequilibrium FDR may depend on both time and the choice of observable, which is fundamentally at odds with the properties of an equilibrium temperature. This caveat has led to the common notion that the effective temperature acquires thermodynamical meaning only if these dependencies are not too pronounced or can be appropriated to separate length-and/or time scales [2,[8][9][10][11][12].For this reason, the effective temperature concept has been so prolific in describing the nonequilibrium properties of glassy systems [7,9]. While fast vibrational fluctuations remain equilibrated with the environment, the slow evolution of the out-of-equilibrium structure is characterized by a higher effective temperature, a scenario known as partial equilibration [7]. During the ageing process, this effective temperature slowly decreases until eventually the environmental temperature is reached on all time scales [2,13]. However, in complex fluids or biological matter this kind of dynamical time-scale separation is the exception rather than the rule. In this regime of mixed time scales, time-dependent FDRs have been studied, i.a., for active matter [5,11,[14][15][16][17][18][19], sheared colloidal suspensions [10,20,21] and single biomolecules [12]. In a heuristic approach introduced in the glassy context [2,7] and revisited for driven Brownian [15,16,22] and ageing [23] systems, the effective temperature is identified with the measurement by a thermometer. However, while in equilibrium any conceivable thermometer must read the same temperature, this is no longer true in the nonequilibrium case, where time scales

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“…One more fact is that underdamped Brownian particles have been investigated much less frequently than overdamped ones, because the latter model is more simple yet widely applicable in many practical cases. Even if the particle inertia is formally considered [19,26,32,[35][36][37][38][39], typically, little attention is paid to its effect on the system response. On the other hand, it was proven that inertial effects play an important role at short time scales [40][41][42][43][44][45].…”

Section: Introductionmentioning

confidence: 99%

Brownian systems perturbed by mild shear: Comparing response relations

Asheichyk,

Fuchs,

Krüger

2021

Preprint

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We present a comprehensive study of the linear response of interacting underdamped Brownian particles to simple shear flow. We collect six different routes for computing the response, two of which are based on the symmetry of the considered system and observable with respect to the shear axes. We include the extension of the Green-Kubo relation to underdamped cases, which shows two unexpected additional terms. These six computational methods are applied to investigate the relaxation of the response towards the steady state for different observables, where interesting effects due to interactions and a finite particle mass are observed. Moreover, we compare the different response relations in terms of their statistical efficiency, identifying their relative demand on experimental measurement time or computational resources in computer simulations. Finally, several measures of breakdown of linear response theory for larger shear rates are discussed.

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Effective confinement as origin of the equivalence of kinetic temperature and fluctuation-dissipation ratio in a dense shear-driven suspension

Cited by 13 publications

References 42 publications

Resonant behavior of trapped Brownian particles in an oscillatory shear flow

Resonant behavior of trapped Brownian particles in an oscillatory shear flow

Driven Brownian particle as a paradigm for a nonequilibrium heat bath: Effective temperature and cyclic work extraction

Brownian systems perturbed by mild shear: Comparing response relations

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